The subject matter herein relates generally to solid state lighting systems and, more particularly, to a light emitting diode (LED) light module.
Solid-state light lighting systems use solid state light sources, such as light emitting diodes (LEDs), and are being used to replace other lighting systems that use other types of light sources, such as incandescent or fluorescent lamps. The solid-state light sources offer advantages over the lamps, such as rapid turn-on, rapid cycling (on-off-on) times, long useful life span, low power consumption, narrow emitted light bandwidths that eliminate the need for color filters to provide desired colors, and so on.
Solid-state lighting systems typically include different components that are assembled together to complete the final system. For example, the system typically consists of a light engine, an optical component and a power supply. It is not uncommon for a customer assembling a lighting system to have to go to many different suppliers for each of the individual components, and then assemble the different components, from different manufacturers together. Purchasing the various components from different sources proves to make integration into a functioning system difficult. This non-integrated approach does not allow the ability to effectively package the final lighting system in a lighting fixture efficiently.
The light engine of the solid state light system generally includes an LED soldered to a circuit board. The circuit board is configured to be mounted in a lighting fixture. The lighting fixture includes the power supply to provide power to the LED. Typically, the circuit board is wired to the lighting fixture using wires that are soldered to the circuit board and the fixture. Generally, wiring the circuit board to the light fixture power source requires several wires and connections. Each wire must be individually joined between the circuit board and the lighting fixture.
Wiring the circuit board with multiple wires generally requires a significant amount of time and space. In fixtures where space is limited, the wires may require additional time to connect. Additionally, having multiple wires to connect requires multiple terminations, increasing the time required to connect the LEDs. Moreover, using multiple wires increases the possibility of mis-wiring the lighting system. In particular, LED light fixtures are frequently installed by unskilled labor, thereby increasing the possibility of mis-wiring. Mis-wiring the lighting system may result in substantial damage to the LED. Also, in a system where wires are soldered between the circuit board and the fixture, the wires and circuit boards become difficult to replace.
Furthermore, the light engines typically generate a lot of heat and it is desirable to use a heat sink to dissipate heat from the system. Heretofore, LED manufacturers have had problems designing a thermal interface that efficiently dissipates heat from the light engine.
A need remains for lighting systems that can be powered efficiently. A need remains for lighting systems with LEDs that have adequate thermal dissipation. A need remains for lighting systems with LEDs that are assembled in an efficient and cost-effective manner. A need remains for a lighting system that may be efficiently configured for an end use application.
In one embodiment, a light module is provided having a light engine that has an LED package having power terminals. A base ring assembly holds the light engine. The base ring assembly has a base ring configured to be mounted to a supporting structure. The base ring has a securing feature. The base ring assembly has a contact holder that holds power contacts. The power contacts are spring biased against the power terminals to create a separable power connection with the power terminals. A top cover assembly is coupled to the base ring. The top cover assembly has a collar surrounding the base ring. The top cover assembly has a securing feature that engages the securing feature of the base ring to couple the collar to the base ring. The collar has a cavity and the optical component is received in the cavity. The optical component is positioned to receive light from the LED package and the optical component is configured to emit the light generated by the LED package.
In another embodiment, a light module is provided having a light engine that has an LED package with power terminals. A base ring assembly holds the light engine. The base ring assembly has a base ring configured to be mounted to a supporting structure. The base ring assembly has a contact holder that holds power contacts. The power contacts are electrically connected to the power terminals. A top cover assembly is coupled to the base ring. The top cover assembly has a collar defining a cavity. The top cover assembly has a pressure spring positioned between the collar and the base ring assembly. The pressure spring engages the contact holder to bias the contact holder against the LED package. An optical component is coupled to the collar and received in the cavity. The optical component is positioned to receive light from the LED package, and the optical component is configured to emit the light generated by the LED package.
In a further embodiment, a light module is provided having a light engine that has an LED package with power terminals. A base ring assembly holds the light engine. The base ring assembly has a base ring configured to be mounted to a supporting structure and a securing feature. The base ring assembly has a contact holder that holds power contacts. The power contacts are spring biased against the power terminals to create a separable power connection with the power terminals. A top cover assembly is coupled to the base ring. The top cover assembly has a collar that surrounds the base ring and has a securing feature that engages the securing feature of the base ring to couple the collar to the base ring. The collar has a cavity and an optic holder is movably coupled to the collar. An optical component is held by the optic holder in the cavity. The optical component is positioned to receive light from the LED package. The optical component is configured to emit the light generated by the LED package. The optical component is movable toward and away from the LED package as the optic holder is moved with respect to the collar.
The light module 210 includes a base ring assembly 230 that holds the light engine 214. The light module 210 includes a top cover assembly 232 that is configured to be coupled to the base ring assembly 230. The light module 210 includes an optical component 234 that is held by the top cover assembly 232 within the base ring assembly 230. The optical component 234 is positioned to receive light emitted from the LED package 216. For example, the optical component 234 may be held within the base ring assembly 230 adjacent to the LED package 216. In the illustrated embodiment, the optical component 234 constitutes a reflector. The optical component 234 may be a different type of component in an alternative embodiment, such as a lens. In the illustrated embodiment, the reflector is manufactured from a metalized plastic body. Alternatively, the reflector may be manufactured from a metal material. The optical component 234 emits the light generated by the LED package 216 from the light module 210.
The light module 210 includes a power connector 236. The power connector 236 includes a power cable 238. Optionally, an the power connector 236 may include an electrical connector terminated to an end of the power cable 238. The power connector 236 is configured to be electrically connected to the light engine 214 to supply power to the LED package 216.
The base ring assembly 230 includes a base ring 240 and a contact holder 242 held by the base ring 240. The base ring 240 is configured to be secured to another structure, such as the device 212. The base ring 240 may be secured to the structure using fasteners 244, which may be threaded fasteners or other types of fasteners in alternative embodiments. Optionally, the structure of the base ring 240 is secured to may be a heat sink that is configured to dissipate heat generated by the light engine 214. The base ring 240 includes one or more securing features 245 used to secure the top cover assembly 232 to the base ring assembly 230. In the illustrated embodiment, the securing feature 245 constitutes external threads on the base ring 240. Other types of securing features may be utilized in alternative embodiments, such as a recess track, a protrusion, a fastener, a latch, and the like.
The base ring 240 includes an opening 246 in a bottom thereof. The opening 246 receives the LED package 216. With the opening 246 being open at the bottom, the LED 216 is configured to be seated on the heat sink or other structure that the base ring 240 is mounted to. The LED package 216 may be loaded into the opening 246 from the top and/or the bottom. In an exemplary embodiment, the LED package 216 may be removed from the opening 246 while the base ring 240 remains fastened to the structure on which the base ring 240 is mounted. For example, the LED package 216 may be removed and replaced with a different LED package 216 without removing the base ring 240. The LED package 216 may be replaced when the LED package 216 has failed and/or when a different LED package having a different lighting effect is desired. Optionally, the LED package 216 may be held within the opening 246 by a friction fit. Other types of securing means may be used in alternative embodiments to hold the LED package 216 within the base ring 240. For example, the contact holder 242 may be used to hold the LED package 216 within the base ring 240.
The contact holder 242 is received within a cavity 248 of the base ring 240. The contact holder 242 includes a dielectric body, such as a plastic body, that is received in the base ring 240. Optionally, the contact holder 242 may be held within the cavity 248 by an interference fit. Alternatively, other securing means, such as fasteners, may be used to hold the contact holder 242 within the base ring 240. Optionally, the contact holder 242 may include crush ribs or other features around the out perimeter that engage the base ring 240 to provide an interference fit between the contact holder 242 and the base ring 240. The contact holder 242 includes an opening 250. When the base ring assembly 230 is assembled, the opening 250 is aligned with the diode 222 such that light emitted form the diode 222 may be directed through the opening 250. Optionally, the contact holder 242 may include a slanted wall 252 extending upward and outward from the opening 250. The slanted wall 252 allows the light emitted from the diode 222 to be directed outward from the diode 222 at an angle.
The contact holder 242 holds a plurality of power contacts 252 (shown in
The top cover assembly 232 includes a collar 260 that is configured to be coupled to the base ring assembly 230. For example, the collar 260 may be threadably coupled to the base ring 240. The top cover assembly 232 includes a pressure spring 262 configured to be positioned between the collar 260 of the top cover assembly 232 and the base ring assembly 230. The top cover assembly 232 includes an optic holder 264 that holds the optical component 234. The optic holder 264 is configured to be coupled to the collar 260. In an exemplary embodiment, the optic holder 264 is movably coupled to the collar 260 such that the relative position of the optic holder 264 may be changed with respect to the position of the collar 260. As such, the position of the optical component 234 may be change with respect to the collar 260.
The collar 260 includes a body defining a cavity 266. The body of the collar 260 may be manufactured from a dielectric material, such as a plastic material. Alternatively, the body of the collar 260 may be manufactured from another material, such as a metal material. The collar 260 has an opening 268 at a bottom of the cavity 266. When the light module 210 is assembled, the opening 268 is aligned with a diode 222 and the opening 250 of the contact holder 242 to allow light emitted from the diode 222 to be emitted from the light module 210.
In the illustrated embodiment, the collar 260 has internal threads 270 proximate to a top 272 of the collar 260. The optic holder 264 may include corresponding threads 274 (shown in
In the illustrated embodiment, the power contacts 254 include spring beams 284 having mating interfaces 286 thereon. The mating interfaces 286 are configured to engage the power terminals 220 when mounted thereto. The spring beams 284 may be deflected when the contact holder 242 is mounted to the LED package 216. Such deflection causes the spring beams 284 to be spring biased against the power terminals 220 to provide a spring force against the power terminals 220.
The ends of the power contacts 254 opposite the mating interfaces 286 are configured to be terminated to corresponding wires of the power cable 238. In the illustrated embodiment, the power contacts 254 have insulation displacement contacts 288 at the ends thereof that are electrically connected to the wires of the power cable 238. The power contacts 254 may be electrically connected to the wires of the power cable 238 using different types of electrical connections. For example, the wires may be soldered to the power contacts 254. The wires of the power cable 238 may include mating contacts at the ends thereof that are electrically connected to the power contacts 254. A circuit board may be used with the power contacts 254 being terminated to the circuit board and the individual wires of the power cable 238 being terminated to the circuit board.
In an exemplary embodiment, a temperature sensor 290 is held by the contact holder 242. The temperature sensor 290 is electrically connected to wires of the power cable 238 by temperature sensor contacts 292. In the illustrated embodiment, the temperature sensor 290 constitutes a compositor that is configured to be electrically connected to the LED package 216 to monitor a temperature the LED package 216 and/or the diode 222. The temperature sensor 290 is exposed at the bottom surface 280 for mounting to the LED package 216.
In an exemplary embodiment, the collar 260 is coupled to the base ring 240. The securing feature 245 of the base ring assembly 230 is coupled to the securing feature 276 of the top cover assembly 232 to secure the top cover assembly 232 to the base ring assembly 230. In the illustrated embodiment, the securing feature 245 of the base ring assembly 230 constitutes external threads on the base ring 240. The securing feature 276 of the top cover assembly 230 constitutes internal threads on the collar 260. The collar 260 is tightened onto the base ring 240 by rotating the collar 260 in a tightening direction. As the collar 260 is tightened, a ledge 299 of the collar 260 engages the pressure spring 262. Further tightening of the collar 260 compresses the pressure spring 262, which forces the pressure spring 262 into the contact holder 242. The pressure exerted on the contact holder 242 by the pressure spring 262 drives the contact holder 242 downward into the heat sink 294. The bottom surface 280 of the contact holder 242 presses against the LED package 216 and drives the LED package 216 into the heat sink 294. The pressure exerted on the contact holder 242 by the pressure spring 262 holds the LED package 216 against the heat sink 294. The pressure spring 262 maintains adequate pressure on the LED package 216 to provide efficient thermal transfer between the LED package 216 and the heat sink 294.
A thermal interface is defined between the heat sink 294 and the bottom of the LED package 216 and heat is transferred from the LED package 216 into the heat sink 294. In an exemplary embodiment, a thermal interface material may be provided between the heat sink 294 and the LED package 216. For example, a thermal epoxy, a thermal grease, or a thermal sheet or film may be provided between the heat sink 294 and the LED package 216. The thermal interface material increases the thermal transfer between the LED package 216 and the heat sink 294. The downward pressure exerted on the LED package 216 by the contact holder 242 maintains a good thermal connection between the LED package 216 and the heat sink 294. The pressure spring 262 is compressed against the contact holder 242 to impart the downward pressure on the contact holder. The pressure spring 262 maintains such downward pressure on the contact holder 242 to force the LED package 216 against the heat sink 294. The pressure spring 262 maintains the needed amount of force on the LED package 216 to hold the LED package 216 in thermal contact with the heat sink 294.
Once the collar 260 is coupled to the base ring 240, the optic holder 264 and the optical component 234 may be coupled to the collar 260. In an exemplary embodiment, a lip 265 of the optical component 234 is received in a slot 267 in the optic holder 264. During assembly, the optic holder 264 is coupled to the collar 260 by threadably coupling the optic holder 264 to the collar 260. The threads 270 engage the threads 274. The amount of rotation of the optic holder 264 with respect to the collar 260 defines the vertical position of the optical component 234 with respect to the diode 222. The optical component 234 is variably positionable with respect to the diode 222 by controlling the position of the optic holder 264 with respect to the collar 260. The position of the optical component 234 with respect to the diode 222 controls the light effect of the light module 210.
Power contacts 316 are electrically connected to the circuit board 302. In the illustrated embodiment, the power contacts 316 are received in vias extending through the circuit board 302. Alternatively, the power contacts 316 may be surface mounted to the circuit board 302. The power contacts 316 includes spring beams 318 that extend outward from the first surface 304. The spring beams 318 are configured to be deflected and provide a spring force when mated to the power terminals 220 (shown in
The base ring assembly 330 includes a base ring 340 and the contact holder 300. The base ring 340 is configured to be mounted to another structure, such as a heat sink. The base ring 340 holds the contact holder 300. The base ring 340 also holds the LED package 216. In an exemplary embodiment, the base ring 340 includes an opening 342 that receives the LED package 216 therein. Optionally, the LED package 216 may be held by an interference fit within the opening 342 to generally maintain a position of the LED package 216 within the base ring 340, such as during assembly of the light module 328 and/or mounting of the light module 328 to the heat sink. The base ring 340 includes securing features 344 for securing the top cover assembly 332 to the base ring assembly 330. In an exemplary embodiment, the securing features 344 constitute external threads on the base ring 340. Other types of securing features may be used in alternative embodiments.
The top cover assembly 332 includes a collar 360 and a pressure spring 362 that is configured to be positioned between the top cover assembly 332 and the base ring assembly 330. The collar 360 functions as an optic holder for holding the optical component 334. In an exemplary embodiment, the optical component 334 is coupled to the collar 360 and is secured thereto in a fixed position with respect to the collar 360. Alternatively, an additional component such as an optical holder may be provided to hold the optical component 334, wherein the optic holder is movable with respect to the collar 360 to change the position of the optical component 334 with respect to the collar 360.
The collar 360 includes a ledge 364 that receives the pressure spring 362. When assembled, the pressure spring 362 is held between the ledge 364 and the contact holder 300. The pressure spring 362 exerts a downward pressure force on the contact holder 300 which forces the contact holder 300 into the LED package 216. The downward pressure force created by the pressure spring 362 helps hold the LED package 216 against the heat sink. In the illustrated embodiment, the pressure spring 362 constitutes a wave spring that extends between the ledge 364 and the contact holder 300 in a wavy configuration. Other types of springs may be used in alternative embodiments to create a downward pressure force against the contact holder.
In an exemplary embodiment, the top cover assembly 332 includes a securing feature 366. In the illustrated embodiment, the securing feature 366 constitutes internal threads on the collar 360. Other types of securing features may be used in alternative embodiments. The securing features 366 engage the securing feature 344 of the base ring assembly 330 to secure the top cover assembly 332 to the base ring assembly 330. For example, during assembly the collar 360 is rotatably coupled to the base ring 340 with the threads of the securing feature 366 engaging the threads of the securing feature 344. As the collar 360 is tightened, the ledge 364 presses down on the pressure spring 362 to force the pressure spring 362 to be compressed against the circuit board 302 of the contact holder 300. Such compression exerts a spring force onto the contact holder 300 which drives the contact holder 300 downward toward the LED package 216. The stand offs 320 extend between the circuit board 302 and the substrate 218 of the LED package 216. The downward pressure of the pressure spring 362 is transferred into the LED package 216 by the stand offs 320. The pressure spring 362 maintains adequate pressure on the LED package 216 to provide efficient thermal transfer between the LED package 216 and the heat sink. The downward pressure holds the LED package 216 against the heat sink to ensure good thermal transfer there between.
The light module 400 includes a base ring assembly 430 and a top cover assembly 432. The top cover assembly 432 is configured to be coupled to the base ring assembly 430. The base ring assembly 430 is configured to be mounted to another structure, such as a heat sink. The base ring assembly 430 holds the light engine 214. The base ring assembly 430 may be coupled to the heat sink using fasteners 434. Other types of securing means may be used in alternative embodiments. The top cover assembly 432 is configured to hold an optical component 436 (shown in
The base ring assembly 430 includes a base ring 440 that is configured to be mounted to the heat sink. The base ring assembly 430 also includes the contact holder 300. The light engine 214 and the contact holder 300 are received in the base ring 440 and secured thereto. The base ring assembly 430 also includes the fasteners 434. Optionally, the fasteners 434 may be used to hold the light engine 214 against the heat sink. In the illustrated embodiment, the fasteners 434 constitute securing features for securing the top cover assembly 432 to the base ring assembly 430. The fasteners 434 may be referred to hereinafter as securing features 434. Other types of securing features may be utilized in alternative embodiments. For example, the securing features may constitute threads, a bayonet type securing feature, or other components that secure the top cover assembly 432 to the base ring assembly 430.
The top cover assembly 432 includes a collar 460 and a pressure spring 462. The collar 460 includes mounting features 464 and the pressure spring 462 includes mounting features 466 that engage the mounting features 464 of the collar 460 to secure the pressure spring 462 to the collar 460. The pressure spring 462 includes a spring plate 468 and side walls 470 extending upward from the spring plate 468. The mounting features 466 extend from the side walls 470. In an exemplary embodiment, the spring plate 468 includes a plurality of spring elements 472 that extend circumferentially around an opening 474. Each of the spring elements 472 is separate from one another and individually deflectable. For example, slits are cut in the spring plate 468 to define the spring elements 472. When assembled, the spring elements 472 engage the contact holder 300 and provide a spring force on the contact holder 300 to force the contact holder 300 against the light engine 214. The downward pressure on the light engine 214 maintains a thermal interface between the light engine 214 and the heat sink. The pressure spring 462 provides the downward force to hold the light engine 214 in thermal contact with the heat sink to ensure good thermal transfer therebetween.
In an exemplary embodiment, the pressure spring 462 includes one or more securing features 476 used to secure the top cover assembly 432 to the base ring assembly 430. For example, the securing features 476 are configured to engage the securing features 434 of the base ring assembly 430. In the illustrated embodiment, the securing features 476 constitute bayonet type connectors that are configured to engage the fasteners 434. The bayonet type connectors are defined by the side walls 470. The side walls 470 are ramped upward and have a non uniform height measured from the spring plate 468. The side walls 470 have a notch 480 formed therein at the end of the ramp surface 478. The fastener 434 is retained within the notch 480 when the top cover assembly 432 is mated with the base ring assembly.
The top cover assembly 432 is assembled by coupling the pressure spring 462 to the collar 460 using the mounting features 464, 466. The optical component 436 may be coupled to the top cover assembly 432 prior to, or after, the top cover assembly 432 is coupled to the base ring assembly 430.
During assembly, the top cover assembly 432 is lowered onto the base ring assembly 430 with the upper head 492 passing through a cut out 494 in the pressure spring 462. The top cover assembly 432 is loaded onto the base ring assembly 430 until the pressure spring 462 rests on the contact holder 300. The top cover assembly 432 is then rotated, such as in a clockwise direction, to a locked position. As the top cover assembly 432 is rotated, the ramp surface 478 engages the upper head 492. The top cover assembly 432 is rotated until the upper head 492 is received in the notch 480 in the side wall 470.
During assembly, as the ramp surface 478 is rotated along the upper head 492, the pressure spring 462 is forced downward. For example, the spring elements 472 are forced downward toward the contact holder 300. The individual spring elements 472 engage the second surface 306 of the circuit board 302. The spring elements 472 are deflected when the spring elements 472 engage the circuit board 302. Such deflection exerts a spring force on the circuit board 302 forcing the circuit board 302 toward the light engine 214. The spring force puts a downward pressure on the circuit board 302, which is transferred to the light engine 214. The downward pressure holds the light engine 214 against the heat sink. The downward pressure is transferred from the circuit board 302 to the light engine 214 by the stand offs 320. The amount of downward pressure on the circuit board 302 from the pressure spring 462 is adequate to ensure good thermal contact between the light engine 302 and the heat sink. The downward spring force from the pressure spring 462 also forces the circuit board 302 toward light engine 214 to hold the power contacts 316 in position for mating with the power terminals (shown in
The power contacts 316 include the spring beams 318 that are spring biased against the power terminals 220 to create a power connection with the power terminals 220. The power contacts 316 are connected to the power terminals 220 at a separable interface. For example, a nonpermanent connection is made between the power contacts 316 and the power terminals 220. No solder is required to create an electrical connection between the power contacts 316 and the power terminals 220.
In an exemplary embodiment, the light module 400 may be disassembled to repair or replace various components of the light module. For example the top cover assembly 432 may be removed to replace the circuit board 302 and/or the light engine 214. The base ring 440 may remain coupled to the heat sink while the circuit board 302 and/or the light engine 214 may be replaced.
Power contacts 516 are electrically connected to the circuit board 502. In the illustrated embodiment, the power contacts 516 are received in vias extending through the circuit board 502. Alternatively, the power contacts 516 may be surface mounted to the circuit board 502. The power contacts 516 includes spring beams 518 that extend outward from the first surface 504. The spring beams 518 are configured to be deflected and provide a spring force when mated to the power terminals 220 (shown in
One or more electronic component(s) 520 are mounted to the circuit board 502. The electronic component(s) 520 may control a power scheme of the circuit board 502. Optionally, the electronic component 520 may be a temperature sensor. Other types of electronic components may be used in alternative embodiments. The electronic component 520 may be a microprocessor or other type of controller for controlling the lighting. The circuit board 502 includes an opening 522 along one side thereof. The opening 522 is configured to be aligned with the diode 222 (shown in
The base ring assembly 530 includes a base ring 540 and the contact holder 500. The base ring 540 is configured to be mounted to another structure, such as a heat sink. The base ring 540 holds the contact holder 500. The base ring 540 also holds the LED package 216. In an exemplary embodiment, the base ring 540 includes an opening 542 aligned with the LED package 216. The base ring 540 is mounted over the LED package 216 such that the opening 542 is aligned with the diode 220.
The top cover assembly 532 includes a collar 560 and a pressure spring 562 that is configured to be positioned between the top cover assembly 532 and the optical component 534. The collar 560 functions as an optic holder for holding the optical component 534. In an exemplary embodiment, the optical component 534 is coupled to the collar 560 and is secured thereto in a fixed position with respect to the collar 560. Alternatively, an additional component such as an optical holder may be provided to hold the optical component 534, wherein the optic holder is movable with respect to the collar 560 to change the position of the optical component 534 with respect to the collar 560.
The collar 560 includes a ledge 564 that receives the pressure spring 562. When assembled, the pressure spring 562 is held between the ledge 564 and the optical component 534. The pressure spring 562 exerts a downward pressure force on the optical component 534 which forces the optical component 534 into the LED package 216. The downward pressure force created by the pressure spring 562 helps hold the LED package 216 against the heat sink. As the collar 560 is tightened, the ledge 564 presses down on the pressure spring 562 to force the pressure spring 562 to be compressed against the optical component 534. In the illustrated embodiment, the pressure spring 562 constitutes a wave spring that extends between the ledge 564 and the optical component 534. Other types of springs may be used in alternative embodiments to create a downward pressure force against the contact holder.
The base ring assembly 530 includes mounting features 572 that receive corresponding mounting features 574 of the optical component 534. In the illustrated embodiment, the mounting features 572 constitute openings that are sized, shaped and positioned to receive complementary mounting features 574. The mounting features 572 orient the optical component 534 with respect to the base ring 540.
The base ring assembly 530 includes securing features 576 used to secure the top cover assembly 532 thereto. The top cover assembly 532 includes complementary securing features 578 that engage the securing features 576 to secure the top cover assembly 532 to the base ring assembly 530. In the illustrated embodiment, the securing features 576, 578 define a bayonet-style coupling. The securing features 576 constitute recessed tracks formed in the side wall of the base ring 540. The securing features 578 constitute protrusions extending inward from the side wall of the collar 560 that are configured to be received in the recessed tracks to secure the top cover assembly 532 to the base ring assembly 530. Alternatively, the securing feature 576 may constitute a protrusion extending out from the side wall and the securing feature 578 may constitute a recessed track in the inner surface of the side wall of the collar 560. Other types of securing features 576, 578 may be used in alternative embodiments. For example, the securing features 576, 578 may constitute threads on the side walls that allow threaded coupling between the collar 560 and the base ring 540. Other examples of securing features 576, 578 include latches, pins, fasteners, and the like that are used to secure the collar 560 with respect to the base ring 540.
In an exemplary embodiment, the securing feature 576 includes a cam surface 580 and a locking notch 582 at an end of the cam surface 580. The cam surface 580 is angled such that as the top cover assembly 532 is rotated in a mating direction, the securing feature 578 rides along the cam surface 580. As the securing feature 578 rides along the cam surface 580, the top cover assembly 532 is drawn downward onto the base ring assembly 530. As the top cover assembly 532 is drawn downward, the pressure spring 562 is compressed against the optical component 534.
During assembly, the top cover assembly 532 is rotated in the mating direction until the securing feature 578 is received in the locking notch 582. The locking notch 582 is notched upward from the cam surface 580 to provide a space that receives the securing feature 578. When the securing feature 578 is received in the locking notch 582, rotation of the top cover assembly 532 in an unmating direction, generally opposite to the mating direction, is restricted.
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means—plus-function format and are not intended to be interpreted based on 35 U.S.C. §112, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
Number | Name | Date | Kind |
---|---|---|---|
4999750 | Gammache | Mar 1991 | A |
6666689 | Savage, Jr. | Dec 2003 | B1 |
7540761 | Weber et al. | Jun 2009 | B2 |
20060262544 | Piepgras et al. | Nov 2006 | A1 |
20080130308 | Behr et al. | Jun 2008 | A1 |
20080316733 | Spartano et al. | Dec 2008 | A1 |
20100135022 | Deguara | Jun 2010 | A1 |
20110194292 | Tsai | Aug 2011 | A1 |
Number | Date | Country | |
---|---|---|---|
20120051068 A1 | Mar 2012 | US |